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Product Manual

Constellation

®

ES Serial ATA

100650923

Rev. F

Standard Models

ST2000NM0011 ST1000NM0011 ST500NM0011

Self-Encrypting Drive Models

ST2000NM0031

ST1000NM0031 ST500NM0031

SED FIPS140-2 Models

ST2000NM0051

ST1000NM0051 ST500NM0051

(2)

© 2013 Seagate Technology LLC. All rights reserved. Publication number: 100650923, Rev. F January 2013

Seagate, Seagate Technology and the Wave logo are registered trademarks of Seagate Technology LLC in the United States and/or

Document Revision History

Revision

Date

Description of Change

Rev. A

02/24/2011

Initial release.

Rev. B

03/23/2011

25, 30-32 & 35.

Rev. C

04/28/2011

fc, 2 & 4.

Rev. D

02/15/2012

fc, 3, 5, 30-33 & 37.

Rev. E

09/05/2012

5 & 7.

(3)

Contents

Seagate® Technology Support Services . . . 1

1.0

Introduction. . . 2

1.1

About the Serial ATA interface . . . 3

2.0

Drive specifications . . . 4

2.1

Specification summary tables . . . 4

2.2

Formatted capacity . . . 5

2.2.1

LBA mode . . . 5

2.3

Default logical geometry . . . 6

2.4

Recording and interface technology . . . 6

2.5

Physical characteristics . . . 6

2.6

Seek time. . . 6

2.7

Start/stop times . . . 7

2.8

Power specifications . . . 7

2.8.1

Power consumption . . . 7

2.8.2

Conducted noise . . . 13

2.8.3

Voltage tolerance . . . 13

2.8.4

Power-management modes. . . 14

2.9

Environmental limits . . . 17

2.9.1

Temperature. . . 17

2.9.2

Humidity . . . 18

2.9.3

Altitude . . . 18

2.9.4

Shock . . . 18

2.9.5

Vibration . . . 18

2.10

Acoustics . . . 19

2.11

Test for Prominent Discrete Tones (PDTs) . . . 19

2.12

Electromagnetic immunity . . . 19

2.13

Reliability . . . 20

2.13.1

Annualized Failure Rate (AFR) and Mean Time Between Failures (MTBF). . . 20

2.14

Agency certification . . . 20

2.14.1

Safety certification . . . 20

2.14.2

Electromagnetic compatibility . . . 20

2.14.3

FCC verification . . . 21

2.15

Environmental protection . . . 22

2.15.1

European Union Restriction of Hazardous Substances (RoHS) Directive . . . 22

2.15.2

China Restriction of Hazardous Substances (RoHS) Directive . . . 22

2.16

Corrosive environment . . . 22

2.17

Reference documents . . . 23

2.18

Product warranty . . . 23

3.0

Configuring and mounting the drive . . . 24

3.1

Handling and static-discharge precautions. . . 24

3.2

Configuring the drive . . . 24

3.3

Serial ATA cables and connectors . . . 24

3.4

Drive mounting . . . 25

4.0

About FIPS. . . 26

5.0

About self-encrypting drives . . . 27

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Contents

5.3

Random number generator (RNG). . . 27

5.4

Drive locking . . . 28

5.5

Data bands . . . 28

5.6

Cryptographic erase . . . 28

5.7

Authenticated firmware download. . . 28

5.8

Power requirements . . . 28

5.9

Supported commands. . . 28

5.10

RevertSP . . . 29

5.11

ATA Security Erase Unit Command on SED SATA drives. . . 29

5.12

Sanitize Device - CRYPTO SCRAMBLE EXT . . . 29

6.0

Serial ATA (SATA) interface . . . 30

6.1

Hot-Plug compatibility . . . 30

6.2

Serial ATA device plug connector pin definitions . . . 30

6.3

Supported ATA commands . . . 31

6.3.1

Identify Device command . . . 33

6.3.2

Set Features command . . . 36

(5)

F

IGURES

Figure 1.

Typical 2TB model 5V & 12V startup and operation current profile . . . 11

Figure 2.

Typical 1TB model 5V & 12V startup and operation current profiles . . . 12

Figure 3.

Typical 500GB model 5V & 12V startup and operation current profiles. . . 13

Figure 4.

Location of the HDA temperature check point . . . 17

Figure 5.

Attaching SATA cabling . . . . 24

Figure 6.

Mounting dimensions—top, side and end view . . . 25

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For information regarding online support and services, visit http://www.seagate.com/www/en-us/about/contact_us/ Available services include:

Presales & Technical support

Global Support Services telephone numbers & business hours

Authorized Service Centers

For information regarding Warranty Support, visit http://www.seagate.com/support/warranty-and-returns/

For information regarding data recovery services, visit http://www.seagate.com/services-software/data-recovery-services/ For Seagate OEM and Distribution partner portal, visit https://direct.seagate.com/portal/system

For Seagate reseller portal, visit http://spp.seagate.com

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1.0

INTRODUCTION

This manual describes the functional, mechanical and interface specifications for the following Seagate Constellation®

ES Serial ATA

model drives:.

Note.

Previous generations of Seagate Self-Encrypting Drive models were called Full Disk Encryption (FDE) models before a differ-entiation between drive-based encryption and other forms of encryption was necessary.

Note.

The Self-Encrypting Drive models indicated on the cover of this product manual have provisions for “Security of Data at Rest” based on the standards defined by the Trusted Computing Group (see www.trustedcomputinggroup.org).

For more information on FIPS 140-2 Level 2 certification see see Section 4.0 on page 26. These drives provide the following key features:

• 7200 RPM spindle speed.

• PowerChoice™ for selectable power savings

• Top Cover Attached motor for excellent vibration tolerance

• High instantaneous (burst) data-transfer rates (up to 600MB per second).

• Perpendicular recording technology provides the drives with increased areal density. • State-of-the-art cache and on-the-fly error-correction algorithms.

• Native Command Queueing with command ordering to increase performance in demanding applications. • Full-track multiple-sector transfer capability without local processor intervention.

• SeaTools™ diagnostic software performs a drive self-test that eliminates unnecessary drive returns. • Support for S.M.A.R.T. drive monitoring and reporting.

• Supports latching SATA cables and connectors.

• Worldwide Name (WWN) capability uniquely identifies the drive.

M

ODEL

N

UMBER

S

ELF

-E

NCRYPTING

D

RIVE

(SED)

FIPS 140-2 L

EVEL

2

ST2000NM0011 No No ST2000NM0031 Yes No ST2000NM0051 Yes Yes ST1000NM0011 No No ST1000NM0031 Yes No ST1000NM0051 Yes Yes ST500NM0011 No No ST500NM0031 Yes No ST500NM0051 Yes Yes

(8)

1.1

A

BOUT THE

S

ERIAL

ATA

INTERFACE

The Serial ATA interface provides several advantages over the traditional (parallel) ATA interface. The primary advantages include: • Easy installation and configuration with true plug-and-play connectivity. It is not necessary to set any jumpers or other configuration

options.

• Thinner and more flexible cabling for improved enclosure airflow and ease of installation. • Scalability to higher performance levels.

In addition, Serial ATA makes the transition from parallel ATA easy by providing legacy software support. Serial ATA was designed to allow you to install a Serial ATA host adapter and Serial ATA disc drive in your current system and expect all of your existing applications to work as normal.

The Serial ATA interface connects each disc drive in a point-to-point configuration with the Serial ATA host adapter. There is no master/ slave relationship with Serial ATA devices like there is with parallel ATA. If two drives are attached on one Serial ATA host adapter, the host operating system views the two devices as if they were both “masters” on two separate ports. This essentially means both drives behave as if they are Device 0 (master) devices.

Note.

The host adapter may, optionally, emulate a master/slave environment to host software where two devices on separate Serial ATA ports are represented to host software as a Device 0 (master) and Device 1 (slave) accessed at the same set of host bus addresses. A host adapter that emulates a master/slave environment manages two sets of shadow registers. This is not a typ-ical Serial ATA environment.

The Serial ATA host adapter and drive share the function of emulating parallel ATA device behavior to provide backward compatibility with existing host systems and software. The Command and Control Block registers, PIO and DMA data transfers, resets, and interrupts are all emulated.

The Serial ATA host adapter contains a set of registers that shadow the contents of the traditional device registers, referred to as the Shadow Register Block. All Serial ATA devices behave like Device 0 devices. For additional information about how Serial ATA emulates parallel ATA, refer to the “Serial ATA: High Speed Serialized AT Attachment” specification. The specification can be downloaded from www.serialata.org.

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2.0

DRIVE SPECIFICATIONS

Unless otherwise noted, all specifications are measured under ambient conditions, at 25°C, and nominal power. For convenience, the phrases the drive and this drive are used throughout this manual to indicate the following drive models:

2.1

S

PECIFICATION SUMMARY TABLES

The specifications listed in the following tables are for quick reference. For details on specification measurement or definition, see the appropriate section of this manual.

Table 1 Drive specifications summary

S

TANDARD MODELS

S

ELF

-E

NCRYPTING

D

RIVE

(SED)

MODELS

FIPS 140-2 L

EVEL

2

MODELS

ST2000NM0011 ST2000NM0031 ST2000NM0051 ST1000NM0011 ST1000NM0031 ST1000NM0051 ST500NM0011 ST500NM0031 ST500NM0051 Drive specification ST2000NM0011 ST2000NM0031 ST2000NM0051 ST1000NM0011 ST1000NM0031 ST1000NM0051 ST500NM0011 ST500NM0031 ST500NM0051 Formatted (512 bytes/sector)* 2TB 1TB 500GB Guaranteed sectors 3,907,029,168 1,953,525,168 976,773,168 Heads 8 4 2 Discs 4 2 1

Bytes per sector 512 Default sectors per track 63 Default read/write heads 16 Default cylinders 16,383 Recording density, KBPI (Kb/in max) 1523 Track density, KTPI (ktracks/in avg.) 237 Areal density, (Gb/in2avg) 324 Spindle speed (RPM) 7200 Internal data transfer (Mb/s max) 1300 Sustained data transfer rate OD

(MB/s max)

152 I/O data-transfer rate (MB/s max) 600

ATA data-transfer modes supported PIO modes 0–4

Multiword DMA modes 0–2 Ultra DMA modes 0–6 Cache buffer 64MB

Weight: (maximum) 710g (1.565 lb) 640g (1.411 lb) 610g (1.345 lb) Average latency 4.16ms

Power-on to ready (sec max) 15 10 7 Standby to ready (sec max) 15 10 7 Track-to-track seek time (ms typical) 0.5 read / 0.8 write

Average seek, read (ms typical) <8.5 Average seek, write (ms typical) <9.5 Startup current (typical) 12V (peak) 2.8A

(10)

* One GB equals one billion bytes when referring to hard drive capacity. Accessible capacity may vary depending on operating environment and formatting. * *During periods of drive idle, some offline activity may occur according to the S.M.A.R.T. specification, which may increase acoustic and power to operational levels.

2.2

F

ORMATTED CAPACITY

Model Formatted capacity*

Guaranteed

sectors Bytes per sector

ST2000NM0011 ST2000NM0031 ST2000NM0051 2TB 3,907,029,168 512 ST1000NM0011 ST1000NM0031 ST1000NM0051 1TB 1,953,525,168

Relative humidity 5% to 90% (operating) 5% to 95% (nonoperating) Relative humidity gradient 30% per hour max Altitude, operating –60.96 m to 3,048 m

(–200 ft to 10,000+ ft) Altitude, nonoperating

(below mean sea level, max)

–60.96 m to 12,192 m (–200 ft to 40,000+ ft) Operational Shock (max at 2 ms) Read 70 Gs / Write 40 Gs

Non-Operational Shock (max at 2 ms) 300 Gs 350 Gs Vibration, operating 5–22 Hz: 0.25 Gs, Limited displacement

22–350 Hz: 0.50 Gs 350–500 Hz: 0.25 Gs Operation Rotational vibration 20–1500Hz: 12.5 rads/s² Vibration, nonoperating 10–500 Hz: 4.9 Grms ref Drive acoustics, sound power (bels)

Idle** 2.7 (typical) 2.9 (max) 2.2 (typical) 2.5 (max) 1.9 (typical) 2.3 (max) Performance seek 3.0 (typical)

3.3 (max)

2.8 (typical) 3.1 (max)

2.7 (typical) 3.0 (max) Nonrecoverable read errors 1 sector per 1015bits read

Annualized Failure Rate (AFR) 0.73% based on 8760 POH

Warranty To determine the warranty for a specific drive, use a web browser to access the following web page:http://www.seagate.com/support/warranty-and-returns/

You will be asked to provide the drive serial number, model number (or part number) and country of purchase. After submitting this information, the system will display the warranty information for your drive.

Load-unload cycles 300,000 (25°C, 50% rel. humidity) (600,000 design life testing) Supports Hotplug operation per

Serial ATA Revision 2.6 specification Yes Drive specification ST2000NM0011 ST2000NM0031 ST2000NM0051 ST1000NM0011 ST1000NM0031 ST1000NM0051 ST500NM0011 ST500NM0031 ST500NM0051

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2.3

D

EFAULT LOGICAL GEOMETRY

C

YLINDERS

R

EAD

/

WRITE HEADS

S

ECTORS PER TRACK

16,383 16 63

LBA mode

When addressing these drives in LBA mode, all blocks (sectors) are consecutively numbered from 0 to n–1, where n isthe number of guaranteed sectors as defined above.

2.4

R

ECORDING AND INTERFACE TECHNOLOGY

Interface Serial ATA (SATA)

Recording method Perpendicular

Recording density, KBPI (Kb/in max) 1523

Track density, KTPI (ktracks/in avg) 237

Areal density (Gb/in2 avg) 324

Spindle speed (RPM) (± 0.2%) 7200

Internal data transfer rate (Mb/s max) 1300

Sustained data transfer rate (MB/s max) 152

I/O data-transfer rate (MB/s max) 600 (Ultra DMA mode 5)

2.5

P

HYSICAL CHARACTERISTICS Weight: (maximum) 2TB models 710g (1.565 lb) 1TB models 640g (1.411 lb) 500GB models 610g (1.345 lb) Cache buffer 64MB (64,768KB)

2.6

S

EEK TIME

Seek measurements are taken with nominal power at 25°C ambient temperature. All times are measured using drive diagnostics. The specifications in the table below are defined as follows:

• Track-to-track seek time is an average of all possible single-track seeks in both directions.

• Average seek time is a true statistical random average of at least 5000 measurements of seeks between random tracks, less overhead.

Table 2:

*Typical seek times (ms) Read Write

Track-to-track 0.5 0.8

Average <8.5 <9.5

Average latency: 4.16

*Measured in performance mode.

Note.

These drives are designed to consistently meet the seek times represented in this manual. Physical seeks, regardless of mode (such as track-to-track and average), are expected to meet the noted values. However, due to the manner in which these drives are formatted, benchmark tests that include command overhead or measure logical seeks may produce results that vary from these specifications.

(12)

2.7

S

TART

/

STOP TIMES

2TB models 1TB models 500GB models

Power-on to Ready (sec) 15 (max) 10 (max) 7 (max)

Standby to Ready (sec) 15 (max) 10 (max) 7 (max)

Ready to spindle stop (sec) 20 (max)

2.8

P

OWER SPECIFICATIONS

The drive receives DC power (+5V or +12V) through a native SATA power connector. See Figure 5 on page 24.

2.8.1 Power consumption

Power requirements for the drives are listed in the table on page 9. Typical power measurements are based on an average of drives tested, under nominal conditions, using 5.0V and 12.0V input voltage at 25°C ambient temperature.

• Spinup power

Spinup power is measured from the time of power-on to the time that the drive spindle reaches operating speed. • Seek mode

During seek mode, the read/write actuator arm moves toward a specific position on the disc surface and does not execute a read or write operation. Servo electronics are active. Seek mode power represents the worst-case power consumption, using only random seeks with read or write latency time. This mode is not typical and is provided for worst-case information.

• Read/write power and current

Read/write power is measured with the heads on track, based on a 16-sector write followed by a 32-ms delay, then a 16-sector read followed by a 32ms delay.

• Operating power and current

Operating power is measured using 40 percent random seeks, 40 percent read/write mode (1 write for each 10 reads) and 20 percent drive idle mode.

• Idle mode power

Idle mode power is measured with the drive up to speed, with servo electronics active and with the heads in a random track location. • Standby mode

During Standby mode, the drive accepts commands, but the drive is not spinning, and the servo and read/write electronics are in power-down mode.

(13)

Table 3 2TB Drive DC power requirements

3.0Gb mode 6.0Gb mode

Voltage +5V +12V +5V +12V

Regulation ±5% ±5% ±5% ±5%

Avg Idle Current * 0.24 0.41 0.24 0.42 Advanced Idle Current *

Idle_A 0.24 0.41 0.24 0.42 Idle_B 0.14 0.36 0.15 0.37 Idle_C 0.14 0.20 0.15 0.20 Standby 0.13 0.02 0.14 0.02 Transition Current * Idle_A (Active) 0.54 1.76 0.54 1.72 Idle_B (Active) 0.60 1.61 0.62 1.57 Idle_C (Active) 0.62 2.39 0.64 2.37 Standby (Active) 0.68 2.72 0.66 2.73 Average Sleep Current 0.13 0.02 0.14 0.02 Maximum Start Current

DC (peak DC) 3σ 0.53 2.10 0.53 2.10 AC (Peak DC) 3σ 0.69 2.78 0.90 2.77 Delayed Motor Start (DC max) 3σ 0.14 0.02 0.14 0.02 Peak operating current (random read):

Typical DC 0.29 0.61 0.30 0.62 Maximum DC 3σ 0.30 0.63 0.31 0.65 Maximum DC(peak) 3σ 1.09 1.65 1.10 1.64 Peak operating current (random write)

Typical DC 0.39 0.53 0.39 0.53 Maximum DC 3σ 0.40 0.54 0.40 0.54 Maximum DC(peak) 3σ 1.16 1.66 1.127 1.65 Peak operating current (sequential read)

Typical DC 0.62 0.42 0.62 0.43 Maximum DC 3σ 0.64 0.44 0.64 0.44 Maximum DC(peak) 3σ 0.94 0.64 0.96 0.66 Peak operating current (sequential write)

Typical DC 0.78 0.42 0.78 0.43 Maximum DC 3σ 0.83 0.44 0.82 0.44 Maximum DC(peak) 3σ 1.18 0.67 1.24 0.642

(14)

Table 4 1TB Drive DC power requirements

3.0Gb mode 6.0Gb mode

Voltage +5V +12V +5V +12V

Regulation ±5% ±5% ±5% ±5%

Avg Idle Current * 0.23 0.28 0.24 0.28 Advanced Idle Current *

Idle_A 0.23 0.28 0.24 0.28 Idle_B 0.14 0.25 0.15 0.25 Idle_C 0.14 0.14 0.15 0.14 Standby 0.13 0.01 0.14 0.02 Transition Current * Idle_A (Active) 0.54 1.46 0.60 1.46 Idle_B (Active) 0.62 1.35 0.60 1.31 Idle_C (Active) 0.62 2.03 0.60 2.05 Standby (Active) 0.66 2.49 0.84 2.51 Average Sleep Current 0.13 0.02 0.14 0.01 Maximum Start Current

DC (peak DC) 3σ 0.99 1.92 0.49 1.90 AC (Peak DC) 3σ 0.76 2.50 0.78 2.59 Delayed Motor Start (DC max) 3σ 0.14 0.02 0.15 0.02 Peak operating current (random read):

Typical DC 0.29 0.46 0.30 0.48 Maximum DC 3σ 0.30 0.56 0.31 0.58 Maximum DC(peak) 3σ 1.12 1.52 1.14 1.55 Peak operating current (random write)

Typical DC 0.39 0.36 0.40 0.37 Maximum DC 3σ 0.40 0.41 0.41 0.41 Maximum DC(peak) 3σ 1.13 1.55 1.14 1.56 Peak operating current (sequential read)

Typical DC 0.61 0.28 0.62 0.27 Maximum DC 3σ 0.63 0.29 0.63 0.29 Maximum DC(peak) 3σ 0.91 0.46 0.99 0.55 Peak operating current (sequential write)

Typical DC 0.79 0.28 0.79 0.28 Maximum DC 3σ 0.82 0.29 0.81 0.29 Maximum DC(peak) 3σ 1.09 0.51 1.12 0.57

(15)

* During periods of drive idle, some offline activity may occur according to the S.M.A.R.T. specification, which may increase acoustic and power to operational levels.

Table 5 500GB Drive DC power requirements

3.0Gb mode 6.0Gb mode

Voltage +5V +12V +5V +12V

Regulation ±5% ±5% ±5% ±5%

Avg Idle Current * 0.37 0.21 0.38 0.21 Advanced Idle Current *

Idle_A 0.37 0.21 0.38 0.21 Idle_B 0.14 0.19 0.15 0.19 Idle_C 0.14 0.12 0.15 0.12 Standby 0.13 0.01 0.14 0.02 Transition Current * Idle_A (Active) 0.78 1.48 0.78 1.42 Idle_B (Active) 0.72 1.19 0.72 1.35 Idle_C (Active) 0.72 2.01 0.72 2.03 Standby (Active) 0.72 2.49 0.72 2.43 Average Sleep Current 0.13 0.01 0.14 0.02 Maximum Start Current

DC (peak DC) 3σ 0.62 1.87 0.62 1.88 AC (Peak DC) 3σ 0.76 2.56 0.80 2.65 Delayed Motor Start (DC max) 3σ 0.14 0.02 0.15 0.02 Peak operating current (random read):

Typical DC 0.32 0.40 0.32 0.40 Maximum DC 3σ 0.32 0.48 0.32 0.47 Maximum DC(peak) 3σ 1.03 1.48 01.06 1.450 Peak operating current (random write)

Typical DC 0.40 0.30 0.41 0.30 Maximum DC 3σ 0.41 0.33 0.42 0.33 Maximum DC(peak) 3σ 1.16 1.44 1.16 1.44 Peak operating current (sequential read)

Typical DC 0.61 0.20 0.62 0.20 Maximum DC 3σ 0.63 0.22 0.64 0.22 Maximum DC(peak) 3σ 0.91 0.43 0.97 0.45 Peak operating current (sequential write)

Typical DC 0.79 0.20 0.79 0.20 Maximum DC 3σ 0.83 0.22 0.84 0.22 Maximum DC(peak) 3σ 1.15 0.40 1.15 0.44

(16)

2.8.1.1 Typical current profiles 2TB model current profile

(17)

1TB model current profile

(18)

500GB model current profile

Figure 3. Typical 500GB model 5V & 12V startup and operation current profiles

2.8.2 Conducted noise

Input noise ripple is measured at the host system power supply across an equivalent 80-ohm resistive load on the +12 V line or an equivalent 15-ohm resistive load on the +5V line.

• Using 12V power, the drive is expected to operate with a maximum of 120mV peak-to-peak square-wave injected noise at up to 10MHz. • Using 5V power, the drive is expected to operate with a maximum of 100mV peak-to-peak square-wave injected noise at up to 10MHz.

Note.

Equivalent resistance is calculated by dividing the nominal voltage by the typical RMS read/write current.

2.8.3 Voltage tolerance

Voltage tolerance (including noise): 5V ± 5%

(19)

2.8.4 Power-management modes

The drive provides programmable power management to provide greater energy efficiency. In most systems, you can control power management through the system setup program. The drive features the following power-management modes:

Active mode

The drive is in Active mode during the read/write and seek operations. • Idle mode

The buffer remains enabled, and the drive accepts all commands and returns to Active mode any time disc access is necessary. • Standby mode

The drive enters Standby mode when the host sends a Standby Immediate command. If the host has set the standby timer, the drive can also enter Standby mode automatically after the drive has been inactive for a specifiable length of time. The standby timer delay is established using a Standby or Idle command. In Standby mode, the drive buffer is enabled, the heads are parked and the spindle is at rest. The drive accepts all commands and returns to Active mode any time disc access is necessary.

• Sleep mode

The drive enters Sleep mode after receiving a Sleep command from the host.In Sleep mode, the drive buffer is disabled, the heads are parked and the spindle is at rest. The drive leaves Sleep mode after it receives a Hard Reset or Soft Reset from the host. After receiv-ing a reset, the drive exits Sleep mode and enters Standby mode with all current translation parameters intact.

• Idle and Standby timers

Each time the drive performs an Active function (read, write or seek), the standby timer is reinitialized and begins counting down from its specified delay times to zero. If the standby timer reaches zero before any drive activity is required, the drive makes a transition to Standby mode. In both Idle and Standby mode, the drive accepts all commands and returns to Active mode when disc access is neces-sary.

Power modes Heads Spindle Buffer

Active Tracking Rotating Enabled

Idle_a ID Biased Rotating Enabled

Idle_b Parked Rotating Enabled

Idle_c Parked Rotating at lower RPM Enabled

Standby Parked Stopped Enabled

(20)

2.8.4.1

Extended Power Conditions - PowerChoiceTM

Utilizing the load/unload architecture a programmable power management interface is provided to tailor systems for reduced power consumption and performance requirements.

The table below lists the supported power conditions available in PowerChoice. Power conditions are ordered from highest power consumption (and shortest recovery time) to lowest power consumption (and longest recovery time) as follows: Idle_a power >= Idle_b power >= Idle_c power >= Standby_z power. The further you go down in the table, the more power savings is actualized. For example, Idle_b results in greater power savings than the Idle_a power condition. Standby results in the greatest power savings.

Each power condition has a set of current, saved and default settings. Default settings are not modifiable. Default and saved settings persist across power-on resets. The current settings do not persist across power-on resets. At the time of manufacture, the default, saved and current settings are in the Power Conditions log match.

PowerChoice is invoked using one of two methods

• Automatic power transitions which are triggered by expiration of individual power condition timers. These timer values may be custom-ized and enabled using the Extended Power Conditions (EPC) feature set using the standardcustom-ized Set Features command interface. • Immediate host commanded power transitions may be initiated using an EPC Set Features "Go to Power Condition" subcommand to

enter any supported power condition. Legacy power commands Standby Immediate and Idle Immediate also provide a method to directly transition the drive into supported power conditions.

PowerChoice exits power saving states under the following conditions

• Any command which requires the drive to enter the PM0: Active state (media access) • Power on reset

PowerChoice provides the following reporting methods for tracking purposes

Check Power Mode Command

• Reports the current power state of the drive Identify Device Command

• EPC Feature set supported flag

• EPC Feature enabled flag is set if at least one Idle power condition timer is enabled Power Condition Log reports the following for each power condition

• Nominal recovery time from the power condition to active • If the power condition is Supported, Changeable, and Savable • Default enabled state, and timer value

• Saved enabled state, and timer value • Current enabled state, and timer value

S.M.A.R.T. Read Data Reports

• Attribute 192 - Emergency Retract Count • Attribute 193 - Load/Unload Cycle Count

Power Condition Name Power Condition ID Description

Idle_a 81H Reduced electronics

Idle_b 82H Heads unloaded. Disks spinning at full RPM

Idle_c 83H Heads unloaded. Disks spinning at reduced RPM

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PowerChoice Manufacture Default Power Condition Timer Values

Default power condition timer values have been established to assure product reliability and data integrity. A minimum timer value threshold of two minutes ensures the appropriate amount of background drive maintenance activities occur. Attempting to set a timer values less than the specified minimum timer value threshold will result in an aborted EPC "Set Power Condition Timer" subcommand.

Setting power condition timer values less than the manufacturer specified defaults or issuing the EPC "Go to Power Condition" subcommand at a rate exceeding the default timers may limit this products reliability and data integrity.

PowerChoice Supported Extended Power Condition Feature Subcommands

EPC Subcommand Description

00H Restore Power Condition Settings

01H Go to Power Condition

02H Set Power Condition Timer

03H Set Power Condition State

PowerChoice Supported Extended Power Condition Identifiers

Power Condition Identifiers Power Condition Name

00H Standby_z 01 - 80H Reserved 81H Idle_a 82H Idle_b 83H Idle_c 84 - FEH Reserved

FFH All EPC Power Conditions

Power Condition Name Manufacturer Default Timer Values

Idle_a 2 min

Idle_b 4 min

Idle_c 10 min

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2.9

E

NVIRONMENTAL LIMITS

Temperature and humidity values experienced by the drive must be such that condensation does not occur on any drive part. Altitude and atmospheric pressure specifications are referenced to a standard day at 58.7°F (14.8°C). Maximum wet bulb temperature is 82°F (28°C).

2.9.1 Temperature

a. Operating

The drive meets the operating specifications over a 41°F to 140°F (5°C to 60°C) drive case temperature range with a maximum tem-perature gradient of 36°F (20°C) per hour.

The maximum allowable drive case temperature is 60°C. See Figure 4 for HDA case temperature measurement location

The MTBF specification for the drive assumes the operating environment is designed to maintain nominal case temperature. The rated MTBF is based upon a sustained case temperature of 104°F (40°C). Occasional excursions in operating temperature between the rated MTBF temperature and the maximum drive operating case temperature may occur without impact to the rated MTBF. However, continual or sustained operation at case temperatures beyond the rated MTBF temperature will degrade the drive MTBF and reduce product reliability.

Air flow may be required to achieve consistent nominal case temperature values (see Section 3.4). To confirm that the required cooling is provided for the electronics and HDA, place the drive in its final mechanical configuration, and perform random write/read operations. After the temperatures stabilize, measure the case temperature of the drive.

b. Non-operating

–40° to 158°F (–40° to 70°C) package ambient with a maximum gradient of 36°F (20°C) per hour. This specification assumes that the drive is packaged in the shipping container designed by Seagate for use with drive.

HDA Temp. Check Point

Figure 4. Location of the HDA temperature check point

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2.9.2 Humidity

2.9.2.1 Relative humidity

Operating: 5% to 90% noncondensing (30% per hour max) Nonoperating: 5% to 95% noncondensing (30% per hour max)

2.9.3

Altitude

Operating: –60.96 m to 3,048 m (–200 ft. to 10,000+ ft.) Nonoperating: –60.96 m to 12,192 m (–200 ft. to 40,000+ ft.)

2.9.4 Shock

All shock specifications assume that the drive is mounted securely with the input shock applied at the drive mounting screws. Shock may be applied in the X, Y or Z axis.

2.9.4.1 Operating shock

These drives comply with the performance levels specified in this document when subjected to a maximum operating shock of 70 Gs (read) and 40 Gs (write) based on half-sine shock pulses of 2ms. Shocks should not be repeated more than two times per second.

2.9.4.2 Nonoperating shock 1TB and 500GB models

The nonoperating shock level that the drive can experience without incurring physical damage or degradation in performance when subsequently put into operation is 350 Gs based on a nonrepetitive half-sine shock pulse of 2ms duration.

2TB models

The nonoperating shock level that the drive can experience without incurring physical damage or degradation in performance when subsequently put into operation is 300 Gs based on a nonrepetitive half-sine shock pulse of 2ms duration.

2.9.5 Vibration

All vibration specifications assume that the drive is mounted securely with the input vibration applied at the drive mounting screws. Vibration may be applied in the X, Y or Z axis.

2.9.5.1 Operating vibration

The maximum vibration levels that the drive may experience while meeting the performance standards specified in this document are specified below.

* Rotary Random Operating Vibration

2.9.5.2 Nonoperating vibration

The maximum nonoperating vibration levels that the drive may experience without incurring physical damage or degradation in performance when subsequently put into operation are specified below.

5–22 Hz 0.25 Gs 22–350 Hz 0.50 Gs 350–500 Hz 0.25 Gs 20 - 1500Hz *(RROV) 12.5 rads/s2 w/RVFF 10–500 Hz Linear Random 4.9 Grms ref

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2.10

A

COUSTICS

Drive acoustics are measured as overall A-weighted acoustic sound power levels (no pure tones). All measurements are consistent with ISO document 7779. Sound power measurements are taken under essentially free-field conditions over a reflecting plane. For all tests, the drive is oriented with the cover facing upward.

Note.

For seek mode tests, the drive is placed in seek mode only. The number of seeks per second is defined by the following equa-tion:

(Number of seeks per second = 0.4 / (average latency + average access time)

Table 6 Fluid Dynamic Bearing (FDB) motor acoustics

Idle* Performance seek

2TB models 2.7 bels (typ)

2.9 bels (max)

3.0 bels (typ) 3.3 bels (max)

1TB models 2.2 bels (typ)

2.5 bels (max)

2.8 bels (typ) 3.1 bels (max)

500GB models 1.9 bels (typ)

2.3 bels (max)

2.7 bels (typ) 3.0 bels (max)

* During periods of drive idle, some offline activity may occur according to the S.M.A.R.T. specification, which may increase acoustic and power to operational levels.

2.11

T

EST FOR

P

ROMINENT

D

ISCRETE

T

ONES

(PDT

S

)

Seagate follows the ECMA-74 standards for measurement and identification of PDTs. An exception to this process is the use of the absolute threshold of hearing. Seagate uses this threshold curve (originated in ISO 389-7) to discern tone audibility and to compensate for the inaudible components of sound prior to computation of tone ratios according to Annex D of the ECMA-74 standards.

2.12

E

LECTROMAGNETIC IMMUNITY

When properly installed in a representative host system, the drive operates without errors or degradation in performance when subjected to the radio frequency (RF) environments defined in the following table:

Table 7 Radio frequency environments

Test Description Performance level Reference standard

Electrostatic

discharge Contact, HCP, VCP: ± 4 kV; Air: ± 8 kV B EN 61000-4-2: 95 Radiated RF immunity 80 to 1000 MHz, 3 V/m, 80% AM with 1 kHz sine 900 MHz, 3 V/m, 50% pulse modulation @ 200 Hz A EN 61000-4-3: 96 ENV 50204: 95 Electrical fast

transient ± 1 kV on AC mains, ± 0.5 kV on external I/O B EN 61000-4-4: 95 Surge immunity ± 1 kV differential, ± 2 kV common, AC mains B EN 61000-4-5: 95 Conducted RF

immunity 150 kHz to 80 MHz, 3 Vrms, 80% AM with 1 kHz sine A EN 61000-4-6: 97 Voltage dips, interrupts 0% open, 5 seconds 0% short, 5 seconds 40%, 0.10 seconds 70%, 0.01 seconds C C C B EN 61000-4-11: 94

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2.13

R

ELIABILITY

2.13.1 Annualized Failure Rate (AFR) and Mean Time Between Failures (MTBF)

The product shall achieve an Annualized Failure Rate (AFR) of 0.73% (MTBF of 1.2 million hours) when operated nominal power and typical case temperatures of 40°C. Operation at temperatures outside the specifications in Section 2.9 may increase the product AFR (decrease MTBF). AFR and MTBF are population statistics that are not relevant to individual units.

AFR and MTBF specifications are based on the following assumptions for business critical storage system environments: • 8760 power-on-hours per year.

• Operations at nominal voltages.

• Temperatures outside the specifications in Section 2.9 may reduce thee product reliability.

• Normal I/O duty cycle for enterprise nearline applications. Operation at excessive I/O duty cycle may degrade product reliability. The enterprise application nearline environment of power-on-hours, temperature, and I/O duty cycle affect the product AFR and MTBF.

2.14

A

GENCY CERTIFICATION

2.14.1 Safety certification

These products are certified to meet the requirements of UL60950-1, CSA60950-1 and EN60950 and so marked as to the certify agency.

2.14.2 Electromagnetic compatibility

Hard drives that display the CE mark comply with the European Union (EU) requirements specified in the Electromagnetic Compatibility Directive (2004/108/EC) as put into place 20 July 2007. Testing is performed to the levels specified by the product standards for Information Technology Equipment (ITE). Emission levels are defined by EN 55022, Class B and the immunity levels are defined by EN 55024.

Drives are tested in representative end-user systems. Although CE-marked Seagate drives comply with the directives when used in the test systems, we cannot guarantee that all systems will comply with the directives. The drive is designed for operation inside a properly designed enclosure, with properly shielded I/O cable (if necessary) and terminators on all unused I/O ports. Computer manufacturers and system integrators should confirm EMC compliance and provide CE marking for their products.

Nonrecoverable read errors 1 per 1015 bits read, max

Annualized Failure Rate (AFR) 0.73% (nominal power, 40°C case temperature) Load unload cycles 300,000 cycles

Warranty To determine the warranty for a specific drive, use a web browser to access the following web page:http://www.seagate.com/support/warranty-and-returns/

From this page, click on the "Verify Your Warranty" link. You will be asked to provide the drive serial number, model number (or part number) and country of purchase.The system will display the warranty information for your drive.

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Korean RRL

If these drives have the Korean Communications Commission (KCC) logo, they comply with paragraph 1 of Article 11 of the Electromagnetic Compatibility control Regulation and meet the Electromagnetic Compatibility (EMC) Framework requirements of the Radio Research Laboratory (RRL) Communications Commission, Republic of Korea.

These drives have been tested and comply with the Electromagnetic Interference/Electromagnetic Susceptibility (EMI/EMS) for Class B products. Drives are tested in a representative, end-user system by a Korean-recognized lab.

• Family name: Constellation ES

• Certificate number:STX-ST2000NM0011 (B) • Date of certification:22 December 2010

Australian C-Tick (N176)

If these models have the C-Tick marking, they comply with the Australia/New Zealand Standard AS/NZ CISPR22 and meet the Electromagnetic Compatibility (EMC) Framework requirements of the Australian Communication Authority (ACA).

2.14.3 FCC verification

These drives are intended to be contained solely within a personal computer or similar enclosure (not attached as an external device). As such, each drive is considered to be a subassembly even when it is individually marketed to the customer. As a subassembly, no Federal Communications Commission verification or certification of the device is required.

Seagate has tested this device in enclosures as described above to ensure that the total assembly (enclosure, disc drive, motherboard, power supply, etc.) does comply with the limits for a Class B computing device, pursuant to SubpartJ, Part 15 of the FCC rules. Operation with noncertified assemblies is likely to result in interference to radio and television reception.

Radio and television interference. This equipment generates and uses radio frequency energy and if not installed and used in strict accordance with the manufacturer’s instructions, may cause interference to radio and television reception.

This equipment is designed to provide reasonable protection against such interference in a residential installation. However, there is no guarantee that interference will not occur in a particular installation. If this equipment does cause interference to radio or television, which can be determined by turning the equipment on and off, you are encouraged to try one or more of the following corrective measures: • Reorient the receiving antenna.

• Move the device to one side or the other of the radio or TV. • Move the device farther away from the radio or TV.

• Plug the computer into a different outlet so that the receiver and computer are on different branch outlets.

If necessary, you should consult your dealer or an experienced radio/television technician for additional suggestions. You may find helpful the following booklet prepared by the Federal Communications Commission: How to Identify and Resolve Radio-Television Interference Problems. This booklet is available from the Superintendent of Documents, U.S. Government Printing Office, Washington, DC 20402. Refer to publication number 004-000-00345-4.

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2.15

E

NVIRONMENTAL PROTECTION

Seagate designs its products to meet environmental protection requirements worldwide, including regulations restricting certain chemical substances.

2.15.1 European Union Restriction of Hazardous Substances (RoHS) Directive

Seagate designs its products to meet environmental protection requirements worldwide, including regulations restricting certain chemical substances. A new law, the European Union Restriction of Hazardous Substances (RoHS) Directive, restricts the presence of chemical substances, including Lead, Cadmium, Mercury, Hexavalent Chromium, PBB and PBDE, in electronic products, effective July 2006. This drive is manufactured with components and materials that comply with the RoHS Directive.

2.15.2 China Restriction of Hazardous Substances (RoHS) Directive

This product has an Environmental Protection Use Period (EPUP) of 20 years. The following table contains information mandated by China's "Marking Requirements for Control of Pollution Caused by Electronic Information Products" Standard.

"O" indicates the hazardous and toxic substance content of the part (at the homogenous material level) is lower than the threshold defined by the China RoHS MCV Standard.

"X" indicates the hazardous and toxic substance content of the part (at the homogenous material level) is over the threshold defined by the China RoHS MCV Standard.

2.16

C

ORROSIVE ENVIRONMENT

Seagate electronic drive components pass accelerated corrosion testing equivalent to 10 years exposure to light industrial environments containing sulfurous gases, chlorine and nitric oxide, classes G and H per ASTM B845. However, this accelerated testing cannot duplicate every potential application environment. Users should use caution exposing any electronic components to uncontrolled chemical pollutants and corrosive chemicals as electronic drive component reliability can be affected by the installation environment. The silver, copper, nickel and gold films used in Seagate products are especially sensitive to the presence of sulfide, chloride, and nitrate contaminants. Sulfur is found to be the most damaging. In addition, electronic components should never be exposed to condensing water on the surface of the printed circuit board assembly (PCBA) or exposed to an ambient relative humidity greater than 95%. Materials used in cabinet fabrication, such as vulcanized rubber, that can outgas corrosive compounds should be minimized or eliminated. The useful life of any electronic equipment may be extended by replacing materials near circuitry with sulfide-free alternatives.

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2.17

R

EFERENCE DOCUMENTS

Self-Encrypting Drives Reference Manual

Seagate part number: 100515636

Trusted Computing Group (TCG) Documents (apply to Self-Encrypting Drive models only) TCG Storage Architecture Core Specification, Rev. 1.0

TCG Storage Security Subsystem Class Enterprise Specification, Rev. 1.0 In case of conflict between this document and any referenced document, this document takes precedence.

2.18

P

RODUCT WARRANTY

Beginning on the date of shipment to the customer and continuing for the period specified in your purchase contract, Seagate warrants that each product (including components and subassemblies) that fails to function properly under normal use due to defect in materials or workmanship or due to nonconformance to the applicable specifications will be repaired or replaced, at Seagate’s option and at no charge to the customer, if returned by customer at customer’s expense to Seagate’s designated facility in accordance with Seagate’s warranty procedure. Seagate will pay for transporting the repair or replacement item to the customer. For more detailed warranty information, refer to the standard terms and conditions of purchase for Seagate products on your purchase documentation.

The remaining warranty for a particular drive can be determined by calling Seagate Customer Service at 1-800-468-3472. You can also determine remaining warranty using the Seagate web site (www.seagate.com). The drive serial number is required to determine remaining warranty information.

Shipping

When transporting or shipping a drive, use only a Seagate-approved container. Keep your original box. Seagate approved containers are easily identified by the Seagate Approved Package label. Shipping a drive in a non-approved container voids the drive warranty.

Seagate repair centers may refuse receipt of components improperly packaged or obviously damaged in transit. Contact your authorized Seagate distributor to purchase additional boxes. Seagate recommends shipping by an air-ride carrier experienced in handling computer equipment.

Storage

The maximum recommended storage period for the drive in a non-operational environment is 90 days. Drives should be stored in the original unopened Seagate shipping packaging whenever possible. Once the drive is removed from the Seagate original packaging the recommended maximum period between drive operation cycles is 30 days. During any storage period the drive non-operational temperature, humidity, wet bulb, atmospheric conditions, shock, vibration, magnetic and electrical field specifications should be followed.

Product repair and return information

Seagate customer service centers are the only facilities authorized to service Seagate drives. Seagate does not sanction any third-party repair facilities. Any unauthorized repair or tampering with the factory seal voids the warranty.

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3.0

CONFIGURING AND MOUNTING THE DRIVE

This section contains the specifications and instructions for configuring and mounting the drive.

3.1

H

ANDLING AND STATIC

-

DISCHARGE PRECAUTIONS

After unpacking, and before installation, the drive may be exposed to potential handling and electrostatic discharge (ESD) hazards. Observe the following standard handling and static-discharge precautions:

Caution:

• Before handling the drive, put on a grounded wrist strap, or ground yourself frequently by touching the metal chassis of a computer that is plugged into a grounded outlet. Wear a grounded wrist strap throughout the entire installation procedure.

• Handle the drive by its edges or frame only.

• The drive is extremely fragile—handle it with care. Do not press down on the drive top cover. • Always rest the drive on a padded, antistatic surface until you mount it in the computer. • Do not touch the connector pins or the printed circuit board.

• Do not remove the installed labels from the drive or cover them with additional labels. Removal voids the warranty. Some factory-installed labels contain information needed to service the drive. Other labels are used to seal out dirt and contamination.

3.2

C

ONFIGURING THE DRIVE

Each drive on the Serial ATA interface connects point-to-point with the Serial ATA host adapter. There is no master/slave relationship because each drive is considered a master in a point-to-point relationship. If two drives are attached on one Serial ATA host adapter, the host operating system views the two devices as if they were both “masters” on two separate ports. Both drives behave as if they are Device 0 (master) devices.

3.3

S

ERIAL

ATA

CABLES AND CONNECTORS

The Serial ATA interface cable consists of four conductors in two differential pairs, plus three ground connections. The cable size may be 30 to 26 AWG with a maximum length of one meter (39.37 in). See Table 8 for connector pin definitions. Either end of the SATA signal cable can be attached to the drive or host.

For direct backplane connection, the drive connectors are inserted directly into the host receptacle. The drive and the host receptacle incorporate features that enable the direct connection to be hot pluggable and blind mateable.

For installations which require cables, you can connect the drive as illustrated in Figure 5.

Figure 5. Attaching SATA cabling

Each cable is keyed to ensure correct orientation. Constellation ES Serial ATA drives support latching SATA connectors.

Power cable Signal cable

Signal connector Power connector

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3.4

D

RIVE MOUNTING

You can mount the drive in any orientation using four screws in the side-mounting holes or four screws in the bottom-mounting holes. See Figure 6 for drive mounting dimensions. Follow these important mounting precautions when mounting the drive:

• Allow a minimum clearance of 0.030 in (0.76mm) around the entire perimeter of the drive for cooling. • Use only 6-32 UNC mounting screws.

• The screws should be inserted no more than 0.150 in (3.81mm) into the bottom or side mounting holes.

Do not overtighten the mounting screws (maximum torque: 6 in-lb).

Weight: (maximum) 2TB models 1TB models 500GB models

710g (1.565 lb) 640g (1.411 lb) 610g (1.345 lb)

Note.

These dimensions conform to the Small Form Factor Standard documented in SFF-8301 and SFF-8323 found at www.sffcommittee.org

Breather Hole

mmin

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4.0

ABOUT FIPS

The Federal Information Processing Standard (FIPS) Publication 140-2 is a U.S. Government Computer Security Standard used to accredit cryptographic modules. It is titled 'Security Requirements for Cryptographic Modules (FIPS PUB 140-2)' and is issued by the National Institute of Standards and Technology (NIST).

Purpose

This standard specifies the security requirements that will be satisfied by a cryptographic module utilized within a security system protecting sensitive but unclassified information. The standard provides four increasing, qualitative levels of security: Level 1, Level 2, Level 3 and Level 4. These levels are intended to cover the wide range of potential applications and environments in which cryptographic modules may be employed.

Seagate Enterprise SEDs

The SEDs referenced in this Product Manual have been validated by CMVP and have been thoroughly tested by a NVLAP accredited lab to satisfy FIPS 140-2 Level 2 requirements. In order to operate in FIPS Approved Mode of Operation, these SEDs require security initialization. For more information, refer to 'Security Rules' section in the 'Security Policy' document uploaded on the NIST website. To reference the product certification visit - http://csrc.nist.gov/groups/STM/cmvp/documents/140-1/1401vend.htm and search for "Seagate".

Level 2 security

Security Level 2 enhances the physical security mechanisms of a Security Level 1 cryptographic module by adding the requirement for tamper-evidence, which includes the use of tamper-evident coatings or seals on removable covers of the module. Tamper-evident coatings or seals are placed on a cryptographic module so that the coating or seal must be broken to attain physical access to the critical security parameters (CSP) within the module. Tamper-evident seals are placed on covers to protect against unauthorized physical access. In addition Security Level 2 requires, at a minimum, role-based authentication in which a cryptographic module authenticates the authorization of an operator to assume a specific role and perform a corresponding set of services.

Figure 7. Example of FIPS tamper evidence labels.

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5.0

ABOUT SELF-ENCRYPTING DRIVES

Self-encrypting drives (SEDs) offer encryption and security services for the protection of stored data, commonly known as “protection of data at rest.” These drives are compliant with the Trusted Computing Group (TCG) Enterprise Storage Specifications as detailed in Section 2.17.

The Trusted Computing Group (TCG) is an organization sponsored and operated by companies in the computer, storage and digital communications industry. Seagate’s SED models comply with the standards published by the TCG.

To use the security features in the drive, the host must be capable of constructing and issuing the following two ATA commands: • Trusted Send

• Trusted Receive

These commands are used to convey the TCG protocol to and from the drive in their command payloads.

5.1

D

ATA ENCRYPTION

Encrypting drives use one inline encryption engine for each port, employing AES-256 data encryption in Cipher Block Chaining (CBC) mode to encrypt all data prior to being written on the media and to decrypt all data as it is read from the media. The encryption engines are always in operation and cannot be disabled.

The 32-byte Data Encryption Key (DEK) is a random number which is generated by the drive, never leaves the drive, and is inaccessible to the host system. The DEK is itself encrypted when it is stored on the media and when it is in volatile temporary storage (DRAM) external to the encryption engine. A unique data encryption key is used for each of the drive's possible16 data bands (see Section 5.5).

5.2

C

ONTROLLED ACCESS

The drive has two security providers (SPs) called the "Admin SP" and the "Locking SP." These act as gatekeepers to the drive security services. Security-related commands will not be accepted unless they also supply the correct credentials to prove the requester is authorized to perform the command.

5.2.1 Admin SP

The Admin SP allows the drive's owner to enable or disable firmware download operations (see Section 5.4). Access to the Admin SP is available using the SID (Secure ID) password or the MSID (Manufacturers Secure ID) password.

5.2.2 Locking SP

The Locking SP controls read/write access to the media and the cryptographic erase feature. Access to the Locking SP is available using the BandMasterX or EraseMaster passwords. Since the drive owner can define up to 16 data bands on the drive, each data band has its own password called BandMasterX where X is the number of the data band (0 through 15).

5.2.3 Default password

When the drive is shipped from the factory, all passwords are set to the value of MSID. This 32-byte random value can only be read by the host electronically over the interface. After receipt of the drive, it is the responsibility of the owner to use the default MSID password as the authority to change all other passwords to unique owner-specified values.

5.3

R

ANDOM NUMBER GENERATOR

(RNG)

The drive has a 32-byte hardware RNG that it is uses to derive encryption keys or, if requested to do so, to provide random numbers to the host for system use, including using these numbers as Authentication Keys (passwords) for the drive’s Admin and Locking SPs.

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5.4

D

RIVE LOCKING

In addition to changing the passwords, as described in Section 5.2.3, the owner should also set the data access controls for the individual bands. The variable "LockOnReset" should be set to "PowerCycle" to ensure that the data bands will be locked if power is lost. In addition "ReadLockEnabled" and "WriteLockEnabled" must be set to true in the locking table in order for the bands "LockOnReset" setting of "PowerCycle" to actually lock access to the band when a "PowerCycle" event occurs. This scenario occurs if the drive is removed from its cabinet. The drive will not honor any data read or write requests until the bands have been unlocked. This prevents the user data from being accessed without the appropriate credentials when the drive has been removed from its cabinet and installed in another system. When the drive is shipped from the factory, the firmware download port is unlocked.

5.5

D

ATA BANDS

When shipped from the factory, the drive is configured with a single data band called Band 0 (also known as the Global Data Band) which comprises LBA 0 through LBA max. The host may allocate Band1 by specifying a start LBA and an LBA range. The real estate for this band is taken from the Global Band. An additional 14 Data Bands may be defined in a similar way (Band2 through Band15) but before these bands can be allocated LBA space, they must first be individually enabled using the EraseMaster password.

Data bands cannot overlap but they can be sequential with one band ending at LBA (x) and the next beginning at LBA (x+1).

Each data band has its own drive-generated encryption key and its own user-supplied password. The host may change the Encryption Key (see Section 5.6) or the password when required. The bands should be aligned to 4K LBA boundaries.

5.6

C

RYPTOGRAPHIC ERASE

A significant feature of SEDs is the ability to perform a cryptographic erase. This involves the host telling the drive to change the data encryption key for a particular band. Once changed, the data is no longer recoverable since it was written with one key and will be read using a different key. Since the drive overwrites the old key with the new one, and keeps no history of key changes, the user data can never be recovered. This is tantamount to an instantaneous data erase and is very useful if the drive is to be scrapped or redispositioned.

5.7

A

UTHENTICATED FIRMWARE DOWNLOAD

In addition to providing a locking mechanism to prevent unwanted firmware download attempts, the drive also only accepts download files which have been cryptographically signed by the appropriate Seagate Design Center.

Three conditions must be met before the drive will allow the download operation:

1. The download must be an SED file. A standard (base) drive (non-SED) file will be rejected. 2. The download file must be signed and authenticated.

3. As with a non-SED drive, the download file must pass the acceptance criteria for the drive. For example it must be applicable to the correct drive model, and have compatible revision and customer status.

5.8

P

OWER REQUIREMENTS

The standard drive models and the SED drive models have identical hardware, however the security and encryption portion of the drive controller ASIC is enabled and functional in the SED models. This represents a small additional drain on the 5V supply of about 30mA and a commensurate increase of about 150mW in power consumption. There is no additional drain on the 12V supply. See the tables in Section 2.8 for power requirements on the standard (non-SED) drive models.

5.9

S

UPPORTED COMMANDS

The SED models support the following two commands in addition to the commands supported by the standard (non-SED) models as listed in Table 9:

• Trusted Send (5Eh) or Trusted Send DMA (5Fh) • Trusted Receive (5Ch) or Trusted Receive DMA (5Dh)

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5.10

R

EVERT

SP

SED models will support the RevertSP feature which erases all data in all bands on the device and returns the contents of all SPs (Security Providers) on the device to their original factory state. In order to execute the RevertSP method the unique PSID (Physical Secure ID) printed on the drive label must be provided. PSID is not electronically accessible and can only be manually read from the drive label or scanned in via the 2D barcode.

5.11

ATA S

ECURITY

E

RASE

U

NIT

C

OMMAND ON

SED SATA

DRIVES

The ATA SECURITY ERASE UNIT command shall support both the Normal and Enhanced erase modes with the following modifications/ additions:

• Normal Erase: Normal erase shall be accomplished by changing the media encryption key for the drive followed by an overwrite opera-tion that repeatedly writes a single sector containing random data to the entire drive. The write operaopera-tion shall bypass the media encryp-tion. On reading back the overwritten sectors, the host will receive a decrypted version, using the new encryption key, of the random data sector (the returned data will not match what was written).

• Enhanced Erase: Enhanced erase shall be accomplished by changing the media encryption key for the drive.

5.12

S

ANITIZE

D

EVICE

- CRYPTO SCRAMBLE EXT

This command cryptographically erases all user data on the drive by destroying the current data encryption key and replacing it with a new data encryption key randomly generated by the drive. Sanitize Device is a command field B4h and Feature field 0011h (CRYPTO SCRAMBLE EXT).

The drive shall support the Sanitize Feature Set as defined in ANSI/INCITS ACS-2 with the exceptions and/or modifications described in this section.

The drive shall not support the OVERWRITE EXT and BLOCK ERASE EXT sub-commands.

Support of the SANITIZE FREEZE LOCK EXT command shall be determined on a customer-specific basis. OEM drives shall support the command.

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6.0

SERIAL

ATA (SATA) INTERFACE

These drives use the industry-standard Serial ATA interface that supports FIS data transfers. It supports ATA programmed input/output (PIO) modes 0–4; multiword DMA modes 0–2, and Ultra DMA modes 0–6.

For detailed information about the Serial ATA interface, refer to the “Serial ATA: High Speed Serialized AT Attachment” specification.

6.1

H

OT

-P

LUG COMPATIBILITY

Constellation ES Serial ATA drives incorporate connectors which enable you to hot plug these drives in accordance with the Serial ATA Revision 2.6 specification. This specification can be downloaded from www.serialata.org.

Caution:

The drive motor must come to a complete stop (Ready to spindle stop time indicated in Section 2.7)

prior to changing the plane of operation. This time is required to insure data integrity.

6.2

S

ERIAL

ATA

DEVICE PLUG CONNECTOR PIN DEFINITIONS

Table 8 summarizes the signals on the Serial ATA interface and power connectors.

Notes:

1. All pins are in a single row, with a 1.27mm (0.050”) pitch.

2. The comments on the mating sequence apply to the case of backplane blindmate connector only. In this case, the mating sequences are:

• the ground pins P4 and P12.

• the pre-charge power pins and the other ground pins. • the signal pins and the rest of the power pins.

3. There are three power pins for each voltage. One pin from each voltage is used for pre-charge when installed in a blind-mate back-Table 8 Serial ATA connector pin definitions

Segment Pin Function Definition Signal S1 Ground 2nd mate

S2 A+ Differential signal pair A from Phy

S3

A-S4 Ground 2nd mate

S5 B- Differential signal pair B from Phy

S6 B+

S7 Ground 2nd mate

Key and spacing separate signal and power segments Power P1 V33 3.3V power

P2 V33 3.3V power

P3 V33 3.3V power, pre-charge, 2nd mate

P4 Ground 1st mate

P5 Ground 2nd mate

P6 Ground 2nd mate

P7 V5 5V power, pre-charge, 2nd mate

P8 V5 5V power

P9 V5 5V power

P10 Ground 2nd mate

P11 Ground or LED signal If grounded, drive does not use deferred spin

P12 Ground 1st mate.

P13 V12 12V power, pre-charge, 2nd mate

P14 V12 12V power

(36)

6.3

S

UPPORTED

ATA

COMMANDS

The following table lists Serial ATA standard commands that the drive supports. For a detailed description of the ATA commands, refer to the Serial ATA: High Speed Serialized AT Attachment specification. See “S.M.A.R.T. commands” on page 37.for details and subcommands used in the S.M.A.R.T. implementation.

Table 9 Supported ATA commands

Command name Command code (in hex)

Check Power Mode E5H

Device Configuration Freeze Lock B1H / C1H Device Configuration Identify B1H / C2H Device Configuration Restore B1H / C0H Device Configuration Set B1H / C3H

Device Reset 08H

Download Microcode 92H

Execute Device Diagnostics 90H

Flush Cache E7H

Flush Cache Extended EAH

Format Track 50H

Identify Device ECH

Idle E3H

Idle Immediate E1H

Initialize Device Parameters 91H

Read Buffer E4H

Read DMA C8H

Read DMA Extended 25H

Read DMA Without Retries C9H

Read Log Ext 2FH

Read Multiple C4H

Read Multiple Extended 29H Read Native Max Address F8H Read Native Max Address Extended 27H

Read Sectors 20H

Read Sectors Extended 24H

Read Sectors Without Retries 21H

Read Verify Sectors 40H

Read Verify Sectors Extended 42H Read Verify Sectors Without Retries 41H

(37)

Seek 70H

Set Features EFH

Set Max Address F9H

Note: Individual Set Max Address com-mands are identified by the value placed in the Set Max Features regis-ter as defined to the right.

Address: Password: Lock: Unlock: Freeze Lock: 00H 01H 02H 03H 04H Set Max Address Extended 37H

Set Multiple Mode C6H

Sleep E6H

S.M.A.R.T. Disable Operations B0H / D9H S.M.A.R.T. Enable/Disable Autosave B0H / D2H S.M.A.R.T. Enable Operations B0H / D8H S.M.A.R.T. Execute Offline B0H / D4H S.M.A.R.T. Read Attribute Thresholds B0H / D1H S.M.A.R.T. Read Data B0H / D0H S.M.A.R.T. Read Log Sector B0H / D5H S.M.A.R.T. Return Status B0H / DAH S.M.A.R.T. Save Attribute Values B0H / D3H S.M.A.R.T. Write Log Sector B0H / D6H

Standby E2H

Standby Immediate E0H

Trusted Send 5EH (SED drives only) Trusted Send DMA 5FH (SED drives only) Trusted Receive 5CH (SED drives only) Trusted Receive DMA 5DH (SED drives only)

Write Buffer E8H

Write DMA CAH

Write DMA Extended 35H

Write DMA FUA Extended 3DH Write DMA Without Retries CBH

Write Log Extended 3FH

Write Multiple C5H

Write Multiple Extended 39H Write Multiple FUA Extended CEH

Write Sectors 30H

Write Sectors Without Retries 31H Write Sectors Extended 34H

Write Uncorrectable 45H

References

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